Resum:

There are several reasons to celebrate the latest advances in the treatment of the infection with HIV. According to the Joint United Nations Programme on HIV/AIDS, the number of new infections dropped by 15%; there is also a decrease by 22% in the number of deaths related to HIV/AIDS. Nevertheless, there are new emerging challenges, i.e. the transmission of drug-resistant HIV-1 strains. Therefore, there is a demand for the continued research for new and more potent antiretroviral agents. The entry of HIV into the cell implies a complex and well-orchestrated series of steps in which both viral and cellular molecules are implied, ending with the production of new viral particles. The HIV gp120 glycoprotein binds to the cellular CD4 receptor and to a chemokine receptor, inducing structural rearrangements that continue with the cellular and viral membrane fusion mediated by the HIV glycoprotein gp41. Hence, the entry of HIV is an essential step of the viral replication that offers an open path for the design of new antiviral compounds that could be added to the repertory of drugs used in the treatment of HIV infection. In coincidence with the recent and highly relevant information of the fusion mechanism occurring during the viral entry, the design of new fusion inhibitors has become one of the most promising and debated areas in the study of entry inhibitors. ADS-J1 was originally selected to bind to gp41 and to inhibit the fusion of membranes. In several assays, including the generation of HIV strains resistant to ADS-J1, our laboratory has proved that ADS-J1 interact with gp120 instead of gp41. A more recent publication suggested that ADS-J1 binds to the pocket region of gp41 preventing the infection by the virus. Here, we confirmed that ADS-J1 interacts with gp120 instead of gp41. Recombination of gp120 into a wild type HIV-1 backbone restored the resistant phenotype. Moreover, time of addition assays clearly demonstrated that ADS-J1 does not interact with gp41. VIRIP was identified as a natural peptide present in human hemofiltrate that inhibits the HIV gp41-mediated membrane fusion. It was suggested that VIRIP interact with the fusion peptide in gp41, therefore blocking the fusion of membranes. With the objective to determine the precise mode of action of VIRIP, we generated a HIV-1 virus resistant to VIR-353, an analogue of VIRIP. Additionally, we determined the most relevant combination of mutations for the resistant phenotype. Recent studies have shown the effectivity of VIR-576, a peptide closely related to VIRIP and VIR-353 in a clinical trial phase I/II. The resistance to VIRIP/VIR-353 took a long time to emerge, suggesting a high genetic barrier to resistance. The mutations responsible for the resistant phenotype affected in large scale the replicative capacity of the virus, nevertheless, several compensatory mutations restored the viral fitness, while the resistance to VIR-353 was unaltered. The antiviral combination of VIR-353 and T20 showed an additive effect in inhibiting viral replication, indicating that VIR-353 appeared no to affect the binding of T20 to gp41 in its antiviral activity, the combination of the two fusion inhibitors showed an additive effect in inhibiting viral replication. In general, our results evidence the plasticity of the HIV envelope glycoproteins. This plasticity is highly remarked when the virus replicates under drug selective pressure, which imposes an additional genetic barrier for the virus to overcome.